Gastrulation in C. elegans* - WormBook

Gastrulation in C. elegans *Jeremy Nance 1,§ , Jen-Yi Lee 2,§† , Bob Goldstein1Skirball Institute and Department of Cell Biology, New York UniversitySchool of Medicine, New York, NY 10016 USA2Department of Biology, University of North Carolina, Chapel Hill, NC27599 USA2,§Table of Contents1. Summary of gastrulation events .................................................................................................. 12. Polarization of gastrulating cells ................................................................................................. 23. Mechanisms of cell ingression .................................................................................................... 44. Patterning cell ingressions ......................................................................................................... 95. Future prospects .................................................................................................................... 106. Acknowledgments ................................................................................................................. 117. References ............................................................................................................................ 11AbstractGastrulation is the process by which the germ layers become positioned in an embryo. C. elegansgastrulation serves as a model for studying the molecular mechanisms of diverse cellular and developmentalphenomena, including morphogenesis, cell polarization, cell-cell signaling, actomyosin contraction andcell-cell adhesion. One distinct advantage of studying these phenomena in C. elegans is that genetic tools canbe combined with high resolution live cell imaging and direct manipulations of the cells involved. Here wereview what is known to date about the cellular and molecular mechanisms that function in C. elegansgastrulation.1. Summary of gastrulation eventsGastrulation in C. elegans is not as overtly dramatic as in many other animal embryos, since cells move onlysmall distances, generally single cell diameters, and the blastocoel space is small. Despite this, gastrulation plays anessential role in development, internalizing endodermal, mesodermal, and germ-line precursors. Gastrulation occurs* Edited by James R. Priess and Geraldine Seydoux. Last revised March 11, 2005. Published September 26, 2005. This chapter should be cited as:Nance, J. et al. Gastrulation in C. elegans (September 26, 2005), WormBook, ed. The C. elegans Research Community, WormBook,doi/10.1895/wormbook.1.23.1, http://www.wormbook.org.Copyright: © 2005 Jeremy Nance, et al. This is an open-access article distributed under the terms of the Creative Commons AttributionLicense, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.§ To whom correspondence should be addressed. E-mail: nance@saturn.med.nyu.edu, jenyilee@berkeley.edu or bobg@unc.edu† Current address: Department of Molecular and Cell Biology, University of California, Berkeley, CA 94720 USA1

Gastrulation in C. eleganswhen small groups of cells ingress at various times into the small blastocoel space. The blastocoel space forms whenspecific surfaces of cells separate from one another in the interior of the embryo. Cells acquire an apical-basalpolarity that is important for the asymmetric pattern of adhesions that produce the blastocoel space. Certain PARproteins adopt apical-basal asymmetries in early embryonic cells and are required to properly pattern cell adhesions.The endoderm is the first tissue to internalize during gastrulation. Ea and Ep, the endoderm precursor cells,constrict their outer (apical) surfaces as they ingress. Apical constriction may provide a force that draws theneighbors of Ea and Ep towards each other, displacing Ea and Ep into the center of the embryo. Myosin accumulatesat the apical surfaces of cells as they ingress, and myosin activity is required for ingression. PAR proteins found onthe apical surface are required for the apical accumulation of myosin in ingressing cells and ingressions areinefficient in PAR-depleted embryos.Cells ingress at reproducible times and positions throughout gastrulation. It is possible that the cellularmechanisms used in Ea and Ep are reused by various other ingressing cells, since myosin also accumulates at theapical surfaces of later ingressing cells. Cell fate appears to play an important role in determining which cellsingress.Movies of C. elegans gastrulation can be seen at the following web sites:http://www.bio.unc.edu/faculty/goldstein/lab/movies.htmlhttp://dev.biologists.org/cgi/content/full/130/22/5339/DC1Variation in gastrulation patterns among other species of nematodes is addressed in another WormBook chapter:Embryological variation during nematode development.2. Polarization of gastrulating cellsThe cell movements of gastrulation begin at the 26-cell stage when the two endodermal precursors, Ea and Ep,move from the surface of the embryo into a small interior cavity called the blastocoel (Sulston et al., 1983). Prior tothe 26-cell stage, the embryo is organized as a hull of cells one cell in radius that is surrounded by a vitellineenvelope and eggshell. Each cell adopts a reproducible position within the hull and has up to three differentmembrane surfaces: an outer surface that faces the vitelline envelope (apical surface), surfaces that contact adjacentcells (lateral surfaces), and a surface that faces cells on the opposite side of the hull (basal surface; Figure 1A). Theblastocoel forms when basal surfaces of cells separate from one another while lateral surfaces remain adherent(Figure 1C,D; Nance and Priess, 2002). The pattern of cell contacts, rather than adhesive differences betweendifferent types of cells, appears to control formation of the blastocoel. For example, a blastocoel-like cavity canform when a single cell (the AB blastomere) is isolated from the embryo and allowed to divide in culture (Figure1B; Nance and Priess, 2002). This observation suggests that cell contacts induce an apical-basal polarization in cellsthat causes their different surfaces to develop different adhesive properties.The localization of certain PAR polarity proteins defines an apical-basal axis in early embryonic cells. PAR-3,a conserved protein with three PDZ domains that is homologous to Drosophila Bazooka, and PAR-2, a RING fingerprotein, are cortically enriched proteins that are required for anterior-posterior polarity and occupy reciprocalanterior and posterior cortical domains in the zygote and germ-line precursor cells (see WormBook chapter:Asymmetric cell division and axis formation in the embryo). During the four-cell stage, PAR proteins develop a newasymmetry along the apical-basal axis of cells (Etemad-Moghadam et al., 1995; Guo and Kemphues, 1995; Boyd etal., 1996; Hung and Kemphues, 1999; Nance and Priess, 2002; Nance et al., 2003). During the early four-cell stage,PAR-3 is present around the entire cortex of somatic cells in the embryo (Figure 2A). By the end of the four-cellstage, when cell separations that give rise to the blastocoel first become apparent, cortical PAR-3 becomes largelyrestricted to apical surfaces (Figure 2B). PAR-2 is localized in a reciprocal pattern at the basolateral cortex (Figure2C,D). Other PAR proteins that are asymmetrically localized in the zygote and germ-line precursors developanalogous apical-basal asymmetries: PAR-6, which contains a single PDZ domain, and PKC-3, an atypical proteinkinase C, are enriched on apical surfaces, and PAR-1, a serine/threonine kinase, is enriched on basolateral surfaces.PAR-3 and PAR-2 exhibit the same asymmetric distributions when ectopic cell contacts are created bycombining blastomeres in culture, suggesting that the pattern of cell contacts establishes apical-basal PARasymmetry (Nance and Priess, 2002). In the zygote, the asymmetric localization of PAR proteins is achieved in part2

Gastrulation in C. elegansby cortical flows generated by an asymmetric anterior contraction of the cortical cytoskeleton (see WormBookchapter: Asymmetric cell division and axis formation in the embryo). Analogous apically directed movements of thecytoskeleton occur along the apical-basal axis of early embryonic cells and may function to establish theapical-basal asymmetry in PAR distribution (Munro et al., 2004).Figure 1. Formation of the blastocoel. Formation of the blastocoel. (A) 26-cell stage embryo. Apical ("a"), lateral ("l") and basal ("b") surfaces of a cellare indicated. The blastocoel (arrowheads) forms between basal surfaces of cells. (B) Descendants of an AB cell that has divided in culture. Ablastocoel-like cavity (arrowhead) is present in the center of the cell cluster. (C-D) Transmission electron micrographs of cell contacts in a 28-cell stageembryo; both panels are shown at the same magnification (bar = 1 µ m). (C) Lateral surfaces of cells are adherent and only occasionally separated by smallseparations (arrowhead). (D) Large separations can form between the basal surfaces of cells. Cell-cell contacts between lateral surfaces are indicated byopposing arrowheads. Modified and reprinted with permission from Nance and Priess (2002).PAR-3, but not PAR-2, is required for the asymmetric pattern of cell adhesions observed during blastocoelformation. Cells in par-3 mutant embryos develop spaces between their lateral surfaces similar to those foundbetween basal surfaces in wild-type embryos (Nance and Priess, 2002). To establish that the role of PAR-3 inapical-basal polarity is direct and not a secondary consequence of earlier defects in anterior-posterior polarity,PAR-3 was depleted from early embryonic cells by fusion to a protein domain (the ZF1 domain of PIE-1; Nance etal., 2003). This domain promotes protein degradation beginning at the four-cell stage (Reese et al., 2000; Nance etal., 2003). Embryos expressing only the hybrid PAR-3 protein (par-3(ZF1) embryos) develop separations betweenthe lateral surfaces of cells indistinguishable from those observed in par-3 mutant embryos. Similar phenotypes are3

Gastrulation in C. elegansobserved in par-6(ZF1) embryos (Figure 3). The target molecules that mediate the cell adhesion functions of PAR-3and PAR-6 have yet to be identified.Figure 2. Apical-basal PAR asymmetry. (A, C) Early four-cell stage embryo co-stained with PAR-3 (A) and PAR-2 (C). PAR-3 (red arrows) localizes tothe entire cortex of somatic cells; PAR-2 (green arrow) is found at basolateral surfaces of somatic cells. (B, D) 7-8 cell embryos. PAR-3 (B) is enriched atapical surfaces of somatic cells and PAR-2 (D) is found at basolateral surfaces. The germ-line precursor, where PAR proteins exhibit anterior-posteriorasymmetries, is indicated with an asterisk in all panels. Modified and reprinted with permission from Nance and Priess (2002).Figure 3. Lateral cell adhesion in par(ZF1) embryos. (A,C) Surface view of a wild-type embryo (A) or an embryo where PAR-6 has been removed byfusion to the ZF1 domain (C, "par-6(ZF1) embryo" ). Spaces (arrows) can be seen between cells in the par-6(ZF1) embryo where lateral cell surfaces donot contact. (B,D) Lateral view of the interior region of a 26-cell stage wild-type embryo (B) or par-6(ZF1) embryo (D). A space (arrow) has formedbetween lateral cell surfaces in the par-6(ZF1) embryo. Bar = 5 µ m. Modified and reprinted with permission from Nance et al. (2003).3. Mechanisms of cell ingressionAs Ea and Ep ingress, their apical surfaces move away from the vitelline envelope and are covered by sixneighboring cells: three MS granddaughters (MSap, MSpa, MSpp), two AB progeny (ABplpa, ABplpp) and P 4(Figure 4, Figure 9B; Lee and Goldstein, 2003). In a lateral view, one MS granddaughter (referred to here as MSxx)and P 4can be seen moving toward each other over the apical surfaces of Ea and Ep. To examine whether the4

Gastrulation in C. eleganseggshell and vitelline envelope may provide necessary physical constraints or a necessary microenvironment to thegastrulating embryo, the eggshell and vitelline envelope were removed (Lee and Goldstein, 2003). Ingressionmovements occur in such devitellinized embryos (Figure 5E-H), indicating that these structures do not providesignals or surfaces essential for ingression.The descendants of AB comprise 16 of the 26 embryonic cells present when gastrulation begins, and severalAB descendants contact Ea and Ep (see Figure 9B). To address whether AB descendants are required for ingressionof Ea and Ep, the P 1cell was isolated from the AB cell at the two cell stage and was allowed to divide in culture(Lee and Goldstein, 2003). Observation of these P 1isolates revealed that MSxx and P 4movements still occur (Figure5I-P), showing that AB descendants are not necessary for gastrulation-like movements and ruling out a model inwhich the complete ring of six neighboring cells is necessary to push the E cells internally.Figure 4. Nomarski time-lapse images of C. elegans gastrulation. Ea and Ep are pseudocolored in green, and neighboring cells are in blue. Arrowsindicate direction of neighboring cell movement. The left panel shows a lateral view, with the P 4and MSxx labeled (MSx is in the first image, and MSxdivides between the first and second images). The right panel shows a ventral view, with Ea and Ep sinking into the embryo. Embryos are oriented anteriorto the left.5

Gastrulation in C. elegansFigure 5. Gastrulation in intact embryos, devitellinized embryos, and P 1isolates. Asterisks indicate Ea and Ep, and arrowheads indicate MSxx and P 4.0 minutes indicates the start of gastrulation movements. (A-D) Time-lapse images of gastrulation in an intact embryo (same embryo as Figure 1C), (E-H)in a devitellinized embryo, and (I-P) in P 1isolates. Variation of starting orientation between intact and devitellinized embryos is due to devitellinization (Aversus E). The two sets of P 1isolate images represent two different division patterns, either in a dumbbell orientation (I-L) or in a linear orientation (M-P).Linear orientation occurs in less than 10% of all P 1isolates. Other division patterns were variations between these two extremes. Scale bar = 10 µ m.Reprinted with permission from Lee and Goldstein (2003).The ingressing endodermal cells control the direction of movement of the neighboring cells (Lee andGoldstein, 2003). P 1isolates can divide into a linear array of cells where MSxx cells and P 4flank Ea and Ep,respectively (Figure 5M-P). In cases where the P 4cell is removed from a P 1isolate, MSxx can still move toward theEa/Ep midline, indicating that the P 4cell does not provide a necessary chemoattractant for MSxx movement. P 1isolates can also be separated into two groups and recombined, effectively rotating the cell groups relative to eachother (Figure 6). When P 1isolates are separated and recombined at the junction of the endodermal cells and eitherMSxx or P 4, MSxx and P 4move toward one another over the surfaces of Ea/Ep, generally in the same plane, as inunmanipulated P 1isolates. However, when Ea and Ep are separated and recombined, MSxx and P 4still move towardthe Ea/Ep boundary, but in random axes. Together, these observations show that the polarity of the ingressingendodermal cells determines the direction of movement of neighboring cells, and suggest that neighboring cells maymove passively.Ingressing cells accumulate the non-muscle myosin NMY-2 at their apical surfaces as they ingress. InDrosophila embryos, myosin accumulates at the apical surfaces of cells that undergo a morphogenetic change calledapical constriction (Young et al., 1991). Apical constriction is also observed in many other systems, includinggastrulating Xenopus bottle cells and ingressing sea urchin primary mesenchyme cells (Keller, 1981; Kimberly andHardin, 1998). During apical constriction, the width of the apical surface is decreased, altering the shape of the cell.Although not as dramatic as in some other systems, the width of the apical surface also decreases as cells ingress in6

Gastrulation in C. elegansC. elegans. Evidence for apical constriction during ingression comes from experiments where fluorescentmicrospheres were used to track cell surface movements (Figure 7). Microspheres on the surfaces of Ea and Ep in P 1isolates move toward the junction between these cells (Lee and Goldstein, 2003). In addition, non-muscle myosinaccumulates at these apical surfaces, and myosin activity is required for ingression (Nance and Priess, 2002; Lee andGoldstein, 2003). These results suggest that an actomyosin-mediated contraction at the apical surface of ingressingcells causes these surfaces to constrict. The ARP-2/3 complex is also required for ingression, but it is not knownwhether it plays a role in apical constriction (Severson et al., 2002).Figure 6. Ea and Ep direct the movement of their neighbors. On the left side of each panel is a schematic drawing of part of a P 1isolate and anexperiment that was performed. Cells in the isolates were separated at the site indicated by the broken line, rotated along the axis indicated by the gray linein A, and then recombined. Black curved arrows indicate the direction of movement of the reference cell. On the right of each panel is a corresponding sideview, in which the P 1isolate is oriented as if viewed from one end, either P 4or MSxx (as indicated). Yellow arrows indicate the direction of movement ofP4 cells and the green arrows indicate the direction of movement of MSxx cells. (A) Separation and recombination of Ea and Ep, with P 4as the referencecell; (B) MSxx and Ea, with P 4as the reference cell; or (C) P 4and Ep, with MSxx as the reference cell. Modified and reprinted with permission from Leeand Goldstein (2003).Myosin accumulation in ingressing cells requires PAR-3 and PAR-6. As during blastocoel formation, corticalPAR-3 and PAR-6 are restricted to the apical surfaces of cells during gastrulation. When these proteins are removedfrom early embryonic cells by tagging with the ZF1 protein degradation domain (see above), cell ingressionsproceed much more slowly than in wild-type and the apical surfaces of ingressing cells do not do not visiblyaccumulate more myosin than neighboring, noningressing cells do (Figure 8; Nance et al., 2003). Thus PAR-3 andPAR-6 function in ingressing cells to promote an apical accumulation of myosin, although it is not yet clear whetherthe visible apical myosin enrichment is a prerequisite or result of apical constriction.7

Gastrulation in C. elegansFigure 7. Apical constriction of Ea and Ep during gastrulation. (A) Kymograph derived from movements of microspheres (white) during gastrulationfrom one film of a wild-type P 1isolate. In the kymograph, the image in each frame of the time-lapse recording is used to generate horizontal lines of imagedata that are pasted together in descending order; hence time is represented on the y-axis. First and last frame used for the kymograph are above and belowthe kymograph, respectively. Asterisks label Ea and Ep, Ea/Ep boundary is marked by yellow arrowhead in still frames and by the yellow line in thekymograph, and the white arrow notes the direction of MSxx movement. The microspheres on Ep can be seen converging toward each other duringgastrulation movements. (B) Summary of microsphere movements from 10 films. Each arrow represents the total displacement and angle of movement byeach microsphere. "X" indicates microspheres that did not exhibit any displacement relative to the cell's displacement. (C) Average of the vectors. Insetsshow the directions of microsphere movement from each quadrant, with the average direction in gray. The average velocity for each set of vectors shownbelow the box. Reprinted with permission from Lee and Goldstein (2003).One surprising finding from studies on embryos depleted of PAR-3 or PAR-6 (see above) is that ingressioncan still occur, albeit slowly, despite the lack of apparent myosin accumulation at the apical cortex (Nance et al.,2003). Whether ingressing cells utilize other mechanims in combination with apical constriction to becomeinternalized is not yet clear. Neither ingressing cells nor spreading neighboring cells appear to use prominentfilopodia or lamellipodia to crawl (Lee and Goldstein, 2003). One mechanism that could contribute to ingression is arolling mechanism of neighboring cells; this is suggested by experiments showing that microspheres coating theapical surface of MSxx cells move toward the endodermal cells (Figure 7; Lee and Goldstein, 2003). Thismechanism might be driven by adhesive differences along surfaces of cells, although no adhesion molecules haveyet been implicated in gastrulation.8

Gastrulation in C. elegansFigure 8. Ingression and apical myosin localization in par(ZF1) embryos. (A, a-c) Ea/p (asterisks) position in the same embryo filmed at the 24-cellstage (a), 28-cell stage (b) and 46-cell stage (c). Ea and Ep are internalized and have divided by the 46-cell stage; two of their descendants are indicatedwith double asterisks. An MSxx cell (black triangle) can be observed moving over the apical surfaces of Ea/Ep. (A, d-f) Ea/p in a par-3(ZF1) embryo at the24-cell stage (d), 28-cell stage (e) and 46-cell stage (f). Ingression is slow and the descendants of Ea/p (double asterisks) can be seen on the surface of theembryo at the 46-cell stage (A,f). (B) Myosin localization during Ea/p ingression. (a-c) Wild-type embryo expressing myosin-GFP filmed at 3 minuteintervals beginning at the 26-cell stage. (d-f) par-3(ZF1) embryo expressing myosin-GFP filmed at 3 minute intervals beginning at the 26-cell stage.Myosin accumulates at the apical surfaces of Ea/p in wild-type (B,c; arrow) but not in par-3(ZF1) embryos (B,f; arrow). Bar = 5µm Modified and reprintedwith permission from Nance et al. (2003).EMB-5, a putative splicing factor (Schierenberg et al., 1980; Nishiwaki et al., 1993), and GAD-1, a WD repeatprotein with some similarity to a transcription initiation factor (Knight and Wood, 1998) are required for ingression,but their roles and the genes that they may regulate have not been defined. Mutations in emb-5 and gad-1 shorten thecell cycle of the endodermal cells, which normally ingress during a single prolonged cell cycle (Schierenberg et al.,1980; Knight and Wood, 1998). Thus EMB-5 and GAD-1 may influence ingression by controlling regulators of thecell cycle.4. Patterning cell ingressionsIngression of the endodermal cells occurs at approximately 90 minutes after the first cell division of theembryo. After the endodermal cells have completed ingression, mesodermal cells and germ cells ingress fromvarious positions on the ventral surface over the next 200 minutes (Figure 9; Sulston et al., 1983; Nance and Priess,2002). Although ingressions occur over much of the ventral surface, specific cells ingress at reproducible times and9

Gastrulation in C. eleganspositions. A cleavage-arrested endodermal precursor will even gastrulate at the time that its daughters normallywould do so (Lahl et al., 2003). These observations suggest that the timing of gastrulation is regulated carefully, andthis regulation is distinct to each cell or group of cells.Several observations suggest that the fate of cells, rather than their ventral position, controls whether theyingress. First, mutations that transform the fates of ingressing cells can prevent the transformed cells fromingressing. For example, genes required for endoderm fate specification are also required for Ea and Ep ingression(ex. skn-1, mom-2, genes in the endoderm determining region; Bowerman et al., 1992; Thorpe et al., 1997; Zhu etal., 1997). Second, transforming the fates of cells can change the time that the transformed cells ingress. Twopopulations of MS descendants ingress at different times and have different fates: a group of cells called wishbonecells ingresses earlier than another group called central cells (Figure 9C; Sulston et al., 1983; Nance and Priess,2002). Central cells can be induced to ingress at the same time as wishbone cells if their fates are converted to thoseof wishbone cells (Nance and Priess, 2002). However, transformed central cells can only be induced to ingressearlier when endodermal cells (which normally lie underneath the central cells) are prevented from ingressing,indicating that cell-cell interactions can also play a role in determining ingression behavior.After cell ingressions are complete, gastrulation culminates with the epiboly of the hypodermal (epidermal)cells (see WormBook chapter: Epidermal morphogenesis). Hypodermal cells are born on the dorsal surface of theembryo and migrate ventrally to encase the embryo in skin.Figure 9. Cell ingressions during gastrulation. (A) Major embryonic cell lineages. Each lineage produces cells that ingress during gastrulation. (B)Position of cell nuclei in a 26-cell stage embryo, lateral perspective, at the onset of gastrulation. Nuclei are colored according to lineage as in (A); ABdescendants that do not produce ingressing cells are shown in gray. Note that most ancestors of ingressing cells are born on or near the ventral surface. (C)Map of the ventral surface showing regions of ingression by lineage, colored as in (A); the map is drawn in two panels for clarity. Times of ingressionwithin each region are indicated in minutes after the two-cell stage. Modified and reprinted with permission from Nance and Priess (2002).5. Future prospectsC. elegans gastrulation serves as a model for studying the molecular mechanisms of diverse cell anddevelopmental phenomena (Dawes-Hoang et al., 2003; Putzke and Rothman, 2003). Whereas some of theunderlying mechanisms of gastrulation have been resolved (see model in Figure 10), many questions remain. Howdoes apical-basal PAR polarity control apical myosin accumulation in ingressing cells? Does cell adhesion play arole in promoting ingression movements? Does the unique cell cycle length in certain ingressing cells play a role inregulating their ingression? How is ingression triggered and coupled to cell fate? Understanding these issues in thismodel system may suggest mechanisms by which cells can become repositioned in diverse organisms.10

Gastrulation in C. elegansFigure 10. Model for C. elegans gastrulation. Cell contacts determine the apical/basal localization of PAR proteins. PAR proteins affect cell adhesionand direct an apical enrichment of myosin. A detectable enrichment may not be required for gastrulation, since gastrulation can occur, although with adelay, in the absence of detectable myosin enrichment. The apical surfaces of Ea and Ep constrict, bringing neighboring cells underneath, between the Ecells and the eggshell, and resulting in the ingression of Ea and Ep. Adhesion and MSxx rolling may also play roles in gastrulation movements. Solidarrows denote established relationships or mechanisms, whereas dashed lines denote hypothesized phenomena. Hatched lines on the E cells in the diagramrepresent the actomyosin network. Light gray line represents part of the eggshell. (modified and reprinted with permission from Lee and Goldstein, 2003and based on results from Nance and Priess, 2002; Lee and Goldstein, 2003; Nance et al., 2003)6. AcknowledgmentsWork on gastrulation by the authors has been supported by Postdoctoral Fellowship Grant PF-02-007-01-DCCfrom the American Cancer Society (J.N.), funding from the Howard Hughes Medical Institute (J.P.), and a PewScholarship in the Biomedical Sciences and NIH R01 grant GM68966 to B.G. (J.-Y.L. and B.G.).7. ReferencesBowerman, B., Eaton, B.A., and Priess, J.R. (1992). skn-1, a maternally expressed gene required to specify the fateof ventral blastomeres in the early C. elegans embryo. Cell 68, 1061–1075. Abstract ArticleBoyd, L., Guo, S., Levitan, D., Stinchcomb, D.T., and Kemphues, K.J. (1996). PAR-2 is asymmetrically distributedand promotes association of P granules and PAR-1 with the cortex in C. elegans embryos. Development 122,3075–3084. AbstractDawes-Hoang, R.E., Zallen, J.A., and Wieschaus, E.F. (2003). Bringing classical embryology to C. elegansgastrulation. Dev. Cell 4, 6–8. Abstract ArticleEtemad-Moghadam, B., Guo, S., and Kemphues, K.J. (1995). Asymmetrically distributed PAR-3 protein contributesto cell polarity and spindle alignment in early C. elegans embryos. Cell 83, 743–752. Abstract Article11

Gastrulation in C. elegansGuo, S., and Kemphues, K.J. (1995). par-1, a gene required for establishing polarity in C. elegans embryos, encodesa putative Ser/Thr kinase that is asymmetrically distributed. Cell 81, 611–620. Abstract ArticleHung, T.J., and Kemphues, K.J. (1999). PAR-6 is a conserved PDZ domain-containing protein that colocalizes withPAR-3 in Caenorhabditis elegans embryos. Development 126, 127–135. AbstractKeller, R.E. (1981). An experimental analysis of the role of bottle cells and the deep marginal zone in gastrulation ofXenopus laevis. J. Exp. Zool. 216, 81–101. Abstract ArticleKimberly, E.L., and Hardin, J. (1998). Bottle cells are required for the initiation of primary invagination in the seaurchin embryo. Dev. Biol. 204, 235–250. Abstract ArticleKnight, J.K., and Wood, W.B. (1998). Gastrulation initiation in Caenorhabditis elegans requires the function ofgad-1, which encodes a protein with WD repeats. Dev. Biol. 198, 253–265. AbstractLahl, V., Halama, C., Schierenberg, E. (2003). Comparative and experimental embryogenesis of Plectidae(Nematoda). Dev. Genes Evol. 213(1), 18–27. AbstractLee, J.-Y., and Goldstein, B. (2003). Mechanisms of cell positioning during C. elegans gastrulation. Development130, 307–320. Abstract ArticleMunro, E., Nance, J., and Priess, J.R. (2004). Cortical flows powered by asymmetrical contraction transport PARproteins to establish and maintain anterior-posterior polarity in the early C. elegans embryo. Dev. Cell 7, 413–424.Abstract ArticleNance, J., Munro, E.M., and Priess, J.R. (2003). C. elegans PAR-3 and PAR-6 are required for apicobasalasymmetries associated with cell adhesion and gastrulation. Development 130, 5339–5350. Abstract ArticleNance, J., and Priess, J.R. (2002). Cell polarity and gastrulation in C. elegans. Development 129, 387–397. AbstractNishiwaki, K., Sano, T., and Miwa, J. (1993). emb-5, a gene required for the correct timing of gut precursor celldivision during gastrulation in Caenorhabditis elegans, encodes a protein similar to the yeast nuclear protein SPT6.Mol. Gen. Genet. 239, 313–322. ArticlePowell-Coffman, J.A., Knight, J., and Wood, W.B. (1996). Onset of C. elegans gastrulation is blocked by inhibitionof embryonic transcription with an RNA polymerase antisense RNA. Dev. Biol. 178, 472–483. ArticlePutzke, A.P., and Rothman, J.H. (2003). Gastrulation: PARtaking of the bottle. Curr. Biol. 13, R223–R225. AbstractArticleReese, K.J., Dunn, M.A., Waddle, J.A., and Seydoux, G. (2000). Asymmetric segregation of PIE-1 in C. elegans ismediated by two complementary mechanisms that act through separate PIE-1 protein domains. Mol. Cell 6,445–455. Abstract ArticleSchierenberg, E., Miwa, J., and von Ehrenstein, G. (1980). Cell lineages and developmental defects oftemperature-sensitive embryonic arrest mutants in Caenorhabditis elegans. Dev. Biol. 76, 141–159. Abstract ArticleSeverson, A.F., Baillie, D.L., and Bowerman, B. (2002). A formin homology protein and a profilin are required forcytokinesis and Arp2/3-independent assembly of cortical microfilaments in the early Caenorhabditis elegansembryo. Curr. Biol. 12, 2066–2075. Abstract ArticleSulston, J.E., Schierenberg, E., White, J.G., and Thomson, J.N. (1983). The embryonic cell lineage of the nematodeCaenorhabditis elegans. Dev. Biol. 100, 64–119. Abstract ArticleThorpe, C.J., Schlesinger, A., Carter, J.C., and Bowerman, B. (1997). Wnt signaling polarizes an early C. elegansblastomere to distinguish endoderm from mesoderm. Cell 90, 695–705. Abstract ArticleYoung, P.E., Pesacreata, T.C., and Kiehart, D.P. (1991). Dynamic changes in the distribution of cytoplasmic myosinduring Drosophila embryogenesis. Development 111, 1–14. Abstract12

Gastrulation in C. elegansZhu, J., Hill, R.J., Heid, P.J., Fukuyama, M., Sugimoto, A., Priess, J.R., and Rothman, J.H. (1997). end-1 encodes anapparent GATA factor that specifies the endoderm precursor in Caenorhabditis elegans embryos. Genes Dev. 11,2883–2896. AbstractAll WormBook content, except where otherwise noted, is licensed under a CreativeCommons Attribution License.13